KR101199846B1 - slot type stack for fuel cell - Google Patents

Abstract

PURPOSE: A slot type stack for fuel cell is provided to facilitate lamination of unit cells and to make repair of fuel cell possible within a range not influencing to other unit cells by replacing only defective cells. CONSTITUTION: A slot type stack for fuel cell comprises: an electrode-electrolyte assembly(13); a plurality of unit cells(10) comprising separator arranged in both sides of an assembly of electrode-electrolyte; and a slot case(20) comprising a plurality of slots for inserting and laminating the plurality of unit cells. A lead terminal is formed in the side end of the unit cell. A voltage measurement terminal is formed in a contact part inside the slot case which is contacted to the side end of the unit cell where the lead terminal is formed.

Description

Slot type stack for fuel cell

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stack for fuel cells, and in particular, by stacking unit cells in a slot case in which a plurality of slots are formed in a height direction to facilitate stacking of unit cells. The present invention relates to a fuel cell slot type stack capable of repairing a fuel cell stack in a range that does not affect other unit cells by removing the slot from the slot.

In general, a fuel cell is a power generation that directly converts chemical energy into electrical energy by an electrochemical reaction caused by hydrogen contained in a hydrocarbon-based material such as methanol, ethanol or natural gas and oxygen in air as a fuel. The system is characterized by the simultaneous use of electricity generated by the electrochemical reaction of fuel gas and oxidant gas and heat by-products thereof without the combustion process.

A fuel cell system using a polymer electrolyte fuel cell (PEMFC), which has been recently developed, is basically a fuel cell body (hereinafter referred to as a stack for convenience), a fuel tank, And a fuel pump for supplying fuel from the fuel tank to the stack, wherein the fuel is reformed in the process of supplying the fuel stored in the fuel tank to the stack to generate hydrogen gas and supply the hydrogen gas to the stack. It may include a reformer.

Therefore, the polymer electrolyte fuel cell supplies the fuel stored in the fuel tank to the reformer by the pumping force of the fuel pump, the reformer reforms the fuel to generate hydrogen gas, and the stack electrochemically reacts the hydrogen gas with oxygen. Electric energy is produced.

In the fuel cell system as described above, the stack that substantially generates electricity is an electrode-electrolyte composite (MEA) for attaching an anode electrode and a cathode electrode with an electrolyte membrane interposed therebetween to oxidize / reduce hydrogen gas and air. And unit cells including a separator plate disposed on both sides of the electrode-electrolyte composite to supply hydrogen gas and air to the electrode-electrolyte composite.

In order to prevent fuel leakage and to have a structure as a battery, the stack having the above-described structure must be fastened and fixed to a plurality of stacked cells. For this purpose, each component is glued together using an adhesive or a constant pressure is applied to the end plate. The method of pressing and tightening is used.

The conventional pressurized fastening structure using the end plate is shown in FIG. 1, and the fuel cell stack fastening structure according to the related art shown in FIG. 1 has two end plates supporting both ends of the fuel cell stack 200. A fastening rod 230 penetrating the hole formed in the 210 and a nut 240 fastened to the male screw formed at the end of the fastening rod 230 and fixed to the end plate.

Therefore, by fastening the nuts formed with female threads to the male threads formed at both ends of the fastening rods penetrating the holes, respectively, it is possible to fasten and fix the stack by pressing both end plates.

However, the above-described conventional structure causes a lot of parts such as bolts, nuts, washers, etc., resulting in an increase in cost, and there is a problem in that a lot of time is required for assembly work and disassembly work.

In addition, in the conventional stack structure assembled as described above, when repair is required, a method of disassembling the bolts and nuts to completely remove the force to maintain the stack and then finding and removing the cell to be repaired and reassembling should be used. . At this time, the fastening retaining the stack is removed and then refastened again to cause damage to the entire cell, and in order to maintain the fastening force before dismantling, it is necessary to check the fastening history such as changing the fastening and fastening it. There is discomfort.

The present invention was devised to solve the problems of the prior art as described above, and by stacking unit cells in a slot case in which a plurality of slots are formed in a height direction, stacking of unit cells is facilitated, and a poor unit cell is obtained. It is an object of the present invention to provide a fuel cell slot type stack capable of repairing a fuel cell stack in a range that does not affect other unit cells by removing only the corresponding unit cell from the slot when it occurs.

In addition, since the output voltage monitoring can be performed for each of the plurality of unit cells stacked in the slot case, it is possible to determine whether each unit cell is in good condition, and to establish and operate an effective operation plan for a fuel cell. The purpose is to provide a slot type stack.

The constituent means of the slot type stack for a fuel cell of the present invention proposed to solve the above problems includes an electrode-electrolyte composite (MEA) and a separator plate disposed on both sides of the electrode-electrolyte composite. It comprises a plurality of unit cells, a slot case having a plurality of slots for inserting and stacking the plurality of unit cells, respectively.

Here, the slot case has a structure in which one side is openable among the four sides, the slot is formed on at least two or more sides of the side other than the openable side, the edge of the unit cell in the horizontal direction By inserting, it is characterized in that it is formed continuously in the height direction horizontally so that the plurality of unit cells can be stacked.

Here, the slots continuously formed in the height direction have a shape in which the irregularities are repeated, and the edge portion of the unit cell is formed smaller than the thickness of the unit cell and inserted into the concave portion of the irregularities.

Here, a lead terminal is formed at a side end of the unit cell, and a voltage measuring terminal is formed at a contact portion inside the slot case contacting the side end of the unit cell in which the lead terminal is formed.

Here, one end of the voltage measuring terminal is characterized in that it is formed to be exposed to the outside of the slot case.

Here, the voltage measuring terminal is preferably formed in the concave or convex portion of the slot formed in the rear portion of the slot case.

In addition, the unit cell is bonded to the gasket by the injection method on the outer side of the separator disposed on one side of the electrode-electrolyte composite, and then the electrode-electrolyte composite is laminated thereon, and then the electrode-electrolyte Bonding the gasket to the outer periphery of the composite by the injection method, and laminated on the separation plate disposed on the other side of the electrode-electrolyte composite thereon, to form a fastening pressure and to apply a sealant along the side of the unit cell It is characterized by being completed.

According to the fuel cell slot type stack according to the present invention having the above-described problems and solving means, since unit cells are stacked in a slot case in which a plurality of slots are formed in a height direction, stacking of unit cells is facilitated, and a poor unit is provided. When a cell is generated, only the unit cell is removed from the slot and replaced, whereby the stack for the fuel cell can be repaired in a range that does not affect other unit cells. Thus, there is an advantage in reducing the time, cost and effort for maintenance of the stack for a fuel cell.

In addition, since the output voltage monitoring can be performed for each of the plurality of unit cells stacked in the slot case, it is possible to determine whether each unit cell is in good condition and to establish and operate an effective driving plan. have.

1 is a schematic view showing a fastening structure of a conventional fuel cell stack.
2 is a perspective view of a slot type stack for a fuel cell according to an exemplary embodiment of the present invention.
3 is an exploded perspective view of a slot type stack for a fuel cell according to an exemplary embodiment of the present invention.
4 is a detailed view of a unit cell and a slot which are components of the slot type stack for a fuel cell according to the present invention.
FIG. 5 is a connection arrangement diagram of a lead terminal and a voltage measuring terminal which are components of a slot type stack for a fuel cell according to the present invention.
6 is a diagram illustrating various arrangements of the voltage measuring terminal of FIG. 5.
7 is a manufacturing process diagram of a unit cell that is a component of the slot type stack for a fuel cell of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of a fuel cell slot type stack of the present invention having the above problems, solutions and effects.

The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

2 is a perspective view of a slot type stack for a fuel cell according to an exemplary embodiment of the present invention, and FIG. 3 is an exploded perspective view.

As shown in Figures 2 and 3, the stack of the slot type for fuel cells according to the present invention is separated on both sides of the electrode-electrolyte composite (MEA) 13 and the electrode-electrolyte composite (13) A slot case 20 having a plurality of unit cells 10 including plates 11 and 15 and a slot 25 into which the plurality of unit cells 10 can be inserted, respectively. It is composed.

The plurality of unit cells 10 are stacked in the horizontally inserted state in the slot case 20 to form a stack. In addition, the slot case 20 does not form a stack using bolts and nuts to be assembled and disassembled as in the prior art, so that the plurality of unit cells 10 may be continuously inserted in the horizontal direction, respectively. By constructing, a stack is constructed. To this end, the slot case 20 has a plurality of slots 25 for inserting and stacking the plurality of unit cells 10, respectively.

The slot case 20 generally has a hexahedron shape in order to stack the unit cells 10 having a rectangular shape horizontally and to stack the unit cells 10 in a vertical direction. Thus, it has a top, bottom and four sides. Four side surfaces of the slot case 20 are defined as a front portion 21, a right side portion 22, a left side portion 23, and a rear side portion 24.

The slot case 20 has a structure in which one side of the four sides is openable. 3 illustrates that the front portion 21 has an openable structure among the four side surfaces. The front part 21 of the openable structure as described above is an entrance for inserting the unit cells 10 into the slot case 20 or removing the unit cells 10 from the slot case 20. The front part 21 of the openable structure forms a stack by inserting and stacking all of the unit cells 10, and then may exist in an open state or may be closed through a separate cover.

A stack is formed by inserting each of the unit cells 10 in a horizontal direction and stacking them in a vertical direction through the front part 21 of the slot case 20 opened as described above. Therefore, a plurality of slots 25 are formed on the inner surface of the slot case 20.

The slots 25 formed on the inner side surface portion of the slot case 20 are formed on at least two side surfaces among side surfaces other than the openable side surface (front surface portion 21). That is, the slot 25 is formed along at least two inner side surfaces of the right side portion 22, the left side portion 23, and the rear side portion 24 of the slot case 20. For example, slots 25 corresponding to each other may be formed at the right side 22 and the left side 23, and the rear side 24 may also be formed at the right side 22 and the left side 23. Slots corresponding to the slots 25 may be formed.

Each of the slots 25 is formed horizontally on the inner surface of the slot case 20, they are formed in a plurality in the vertical direction to form the entire slot. As shown in FIG. 3, the slot 25 inserts the edge 17 of the unit cell 10 in a horizontal direction so that the plurality of unit cells 10 can be stacked in a horizontal height direction. Are formed continuously.

The structure of the slot 25 continuously formed in the height direction will be described in detail with reference to FIG. 4.

The slots 25 formed horizontally along the inner side surface of the slot case 20 and they are continuously formed in the height direction have a shape in which irregularities are repeated as shown in FIG. 4. That is, the overall shape of the slots continuously formed in the height direction is a structure in which the irregularities are repeated, and thus, the concave portion 25a and the convex portion 25b are repeated.

The concave portion 25a and the convex portion 25b constituting the one slot 25 allow the one unit cell 10 to be inserted and seated. Therefore, the edge portion 17 of the unit cell 10 inserted into the slot 25 is formed smaller than the thickness of the center portion of the unit cell 10, as shown in FIG. It has a structure that can be inserted into the recess 25a.

Specifically, the edge portion 17 of the unit cell corresponding to the portion inserted into the slot 25 corresponds to a surface bent in a direction perpendicular to the top and bottom surfaces of the unit cell 10. End portions 17a and end portions of the insertion portion 17b extending from the mounting portion 17a and protruding in a horizontal direction with the upper and lower surfaces of the unit cell 10. It consists of a seating portion (17c) corresponding to the surface constituting the.

The edge portion 17 of the unit cell 10 formed as described above is mounted in a state of being inserted into the uneven slot 25. Specifically, each of the unit cells 10 is inserted into each of the slots 25 are mounted, of the edge portion 17 of the unit cell 10, the mounting portion (17a) is the slot 25 It is mounted in contact with the convex portion 25b of the, the insertion portion 17b of the rim portion 17 is inserted into contact with the side of the concave portion 25a, the seating portion 17c of the rim portion 17 ) Is inserted into the seated state in contact with the bottom surface of the recess 25a.

Accordingly, each of the unit cells 10 is inserted into each of the corresponding slots 25, and the plurality of unit cells 10 inserted into the corresponding slots 25 are stacked in the vertical direction in surface contact with each other. It will make up the entire stack.

As described above, each of the unit cells 10 are inserted into the corresponding slots 10, and the unit cells 10 inserted in this way are stacked in a vertical direction to form an entire stack. The fuel cell stack can be easily configured, and when a defective unit cell is generated, only the unit cell 10 can be easily taken out of the corresponding slot 25 and replaced with another normal unit cell 10 easily. Therefore, the slot type stack for a fuel cell according to the present invention has advantages of being very easy to combine and dismantle, and very easy to maintain and repair.

On the other hand, in the present invention is configured to be able to monitor the performance of the performance of the plurality of unit cells 10 are inserted into the slot case 20 stacked. In other words, by monitoring the voltage of each unit cell during operation of the fuel cell, when the performance degradation of a specific unit cell occurs and the voltage deviation between the unit cells increases, the operation logic reflecting the monitored information is established to operate in advance. In order to control so as not to adversely affect other unit cells, the voltage monitoring for each unit cell may be performed.

To this end, as shown in FIG. 5, a lead terminal 19 is formed at the side end of each unit cell 10. In addition, the voltage measuring terminal 27 is provided at the contact portion 26 inside the slot case 20 that is in contact with the side end of the unit cell 10 having the lead terminal 19 formed at the side end of the unit cell 10. Is formed.

Since the voltage measuring terminal 27 is formed on the inner side surface of the slot case 20 in contact with the side end of the unit cell 10 in which the lead terminal 19 is formed, the right side portion 22 and the left side portion ( 23) and the rear portion 24 may be formed on the inner side of any one side portion. In addition, since the plurality of unit cells 10 are stacked in the slot case 20, a plurality of contact parts 26 and voltage measuring terminals 27 are formed in the vertical direction on the inner surface of the slot case 20.

As described above, the voltage measuring terminal 27 may be formed on the inner side surface of any one of the right side part 22, the left side part 23, and the rear part 24, and the right side part 22 and the right side part 22. Since the left surface portion 23 corresponds to a surface that slides in the process of inserting the unit cell 10, the voltage measuring terminal 27 is continuously formed in a direction perpendicular to the inner surface of the rear surface 24. desirable.

Accordingly, the lead terminal 19 formed at the side end of the unit cell 10 has an inner side surface of the rear part 24 when the unit cell 10 is inserted in the horizontal direction through the front part 21. It is preferably formed at the side end of the unit cell 10 corresponding to the surface facing. As a result, the contact portion 26 corresponding to the portion on the inner surface of the slot case 20 in contact with the side end of the unit cell 10 in which the lead terminal 19 is formed and the voltage measurement terminal formed in the contact portion 27 is formed on the inner side of the rear part 24 of the slot case 20.

6 illustrates various arrangements of the contact portion 26 and the voltage measuring terminal 27 formed on the inner surface of the rear portion 24 of the slot case 20.

6 (a) shows that the voltage measuring terminal 27 is formed in the contact portion 26, and is extended in a horizontal direction on the contact portion 26. As shown in FIG. At this time, one end (exposure portion 27a) of the voltage measuring terminal 27 is formed to be exposed to the outside of the slot case 20, as shown in (a) of FIG. By connecting a signal line to the exposed part 27a of the voltage measuring terminal 27, voltage monitoring of the unit cell 10 can be performed.

6B, the slot 25 is formed on the inner side of the rear part 24 of the slot case 20, and the contact part 26 and the voltage measuring terminal 27 are formed in the slot 25. Illustrate what is formed. As a result, the voltage measuring terminal 27 is formed in the concave portion 25a or the convex portion 25b of the slot 25 formed in the rear portion 24 of the slot case 20.

That is, the bottom surface of the concave portion 25a becomes the contact portion 26 or the convex portion 25b becomes the contact portion 26 so that the bottom surface or the convex portion 25b of the concave portion 25a. The voltage measuring terminal 27 is formed. Of course, even in this case, one end (exposure portion 27a) of the voltage measuring terminal 27 is formed to be exposed to the outside of the slot case 20, as shown in FIG. By connecting a signal line to the exposed part 27a of the voltage measuring terminal 27, voltage monitoring of the unit cell 10 can be performed.

When the voltage measuring terminal 27 is formed in the recess 25a, the lead terminal 19 is formed in the seating portion 17c of the unit cell 10, and the voltage measuring terminal 27 is provided. Is formed in the convex portion 25b, the lead terminal 19 is formed in the mounting portion 17a of the unit cell 10.

6 (a) and 6 (b) show that the voltage measuring terminal 27 extends along the contact portion 26 to the right side portion 22 or the left side portion 23 of the slot case 20. Exposing the exposed portion 27a is formed, as shown in (c) of FIG. 6, the exposed portion 27a may be formed to be exposed to the rear portion (24). That is, the voltage measuring terminal 27 is not formed to extend horizontally along the contact portion 26, but may be formed to pass through the rear portion 24 and be exposed to the outside.

Of course, even in this case, one end (exposure portion 27a) of the voltage measuring terminal 27 is formed to be exposed to the outside of the slot case 20, as shown in FIG. By connecting a signal line to the exposed part 27a of the voltage measuring terminal 27, voltage monitoring of the unit cell 10 can be performed.

Since the slot type stack for fuel cells according to the present invention configured as described above can be stacked by inserting each unit cell through the slot, the stack configuration can be easily assembled, and lead terminals are formed in each unit cell. Since the voltage measuring terminal 27 in contact with the terminal is formed in the contact portion and exposed to the outside, voltage monitoring can be performed for each single cell, and a poor unit cell is obtained through the voltage monitoring for each unit cell. If found, since only the unit cell can be easily removed from the slot and replaced, there is an advantage of easy maintenance and repair.

Meanwhile, as described above, the plurality of unit cells 10 inserted into the plurality of slots of the slot case 20 may be manufactured in individual units and inserted into each slot. Therefore, in order to configure the slot type stack for a fuel cell according to the present invention, a plurality of unit cells must be manufactured in advance.

Each unit cell 10 is manufactured and completed through the procedure shown in FIG. 7. That is, as shown in FIG. 7A, the unit cell 10 is first injected into a gasket (outside) of the separator 11 disposed on one side of the electrode-electrolyte composite 13. Join 11a). Airtightness may be maintained between the separator 11 and the electrode-electrolyte composite 13 through the gasket 11a.

In addition, the electrode-electrolyte composite 13 is stacked on the separator 11 formed along the outer edge of the gasket 11a. Then, as shown in FIG. 7B, the gasket 13a is bonded to the outer portion of the electrode-electrolyte composite 13 by injection, and the electrode-electrolyte composite 13 of the electrode 13 is bonded thereon. The separation plate 15 disposed on the other side is stacked. Airtightness may be maintained between the separator 13 and the electrode-electrolyte composite 13 through the gasket 13a.

Then, as shown in (c) of FIG. 7, in the state in which the separator 11, the electrode-electrolyte composite 13, and the separator 15 are combined, a fastening pressure is formed and the unit cell is formed. The unit cell 10 is completed by applying a sealant 15a along the side surface of the container 10. That is, in a state in which the separator 11, the electrode-electrolyte composite 13, and the separator 15 are coupled, the clamping pressure is applied, and then the self-tightening pressure of the unit cell in which the clamping pressure is formed is maintained. In addition, the sealant 15a is applied to the outside of the unit cell 10 to maintain the airtightness when stacked with other unit cells 10 to complete each unit cell 10.

Although the above has been illustrated and described with respect to preferred embodiments of the present invention, the present invention is not limited to the above-described specific embodiments, it is usually in the art without departing from the gist of the invention claimed in the claims. Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

10: unit cell 11, 15: separation plate
11a, 13a: Gasket 15a: Sealant
13: electrode-electrolyte composite 17: edge of the unit cell
17a: mounting portion 17b: insertion portion
17c: seating portion 19: lead terminal
20: slot case 21: the front
22: right side part 23: left side part
24: rear portion 25: slot
25a: concave portion 25b: convex portion
26 contact portion 27 voltage measurement terminal
27a: exposed part of voltage measurement terminal

Claims (7)

A plurality of unit cells including an electrode-electrolyte composite (MEA) and separator plates disposed on both sides of the electrode-electrolyte composite;
A slot case having a plurality of slots for inserting and stacking the plurality of unit cells, respectively;
And a lead terminal is formed at a side end of the unit cell, and a voltage measuring terminal is formed at a contact portion inside the slot case contacting the side end of the unit cell in which the lead terminal is formed.
The method according to claim 1,
The slot case has a structure in which one side is openable among four side surfaces, and the slot is formed in at least two or more sides among side surfaces other than the openable side, and inserts an edge of the unit cell in a horizontal direction. And a slot type stack for a fuel cell, wherein the plurality of unit cells are continuously formed in a horizontal direction so as to stack the plurality of unit cells.
The method according to claim 2,
The slot formed continuously in the height direction has a shape in which the irregularities are repeated, and the edge portion of the unit cell is formed smaller than the thickness of the unit cell and inserted into the concave portion of the irregularities. Type stack.
delete The method according to claim 1,
One end of the voltage measuring terminal is formed to be exposed to the outside of the slot case slot type stack for fuel cells.
The method according to claim 5,
The voltage measuring terminal is a fuel cell slot type stack, characterized in that formed in the concave or convex portion of the slot formed in the rear portion of the slot case.
The method according to any one of claims 1 to 3, 5 and 6,
The unit cell is bonded to the gasket by the injection method on the outer side of the separator disposed on one side of the electrode-electrolyte composite, and then laminated on the electrode-electrolyte composite, and then the electrode-electrolyte composite Bonding the gasket by the injection method to the outside of the, laminated on the separation plate disposed on the other side of the electrode-electrolyte composite thereon, forming a fastening pressure and applying a sealant along the side of the unit cell is completed Slot type stack for fuel cells.

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